SU1743374A3 - Method of forming of linear raster of color picture tube with a slit mask - Google Patents

Abstract

The present invention is an improvement in a method of screening a line screen slit mask color picture tube. Such method includes coating a faceplate panel of the tube with a photosensitive material, inserting a slit shadow mask into the panel and exposing the photosensitive material by passing light from a line light source through the slits of the mask. Such method further comprises positioning a generally cylindrical shaped lens between the line light source and the faceplate panel during exposure of the photosensitive material. The longitudinal axis of the lens is oriented perpendicular to the longitudinal axis of the line light source. The improvement comprises moving both the faceplate panel and the cylindrical shaped lens in synchronization in a direction parallel to the line light source during the exposing step.

Description

The invention relates to the field of color television and can be used to obtain a linear raster in color kinescopes using photo printing techniques, using a slotted shadow mask of a kinescope as a photomask.

A known method of forming a linear raster of color kinescopes with a slit mask consists in applying a photosensitive material to the screen panel, placing a shadow mask inside the panel, exposing the photosensitive material with light from a linear source through a cylindrical lens, the longitudinal axes of which are mutually perpendicular, and the shadow mask.

According to this method, when the screen moves during the formation of the raster, the projected image of the linear source moves at the corners of the screen due to

whereby the phosphor line covers an area somewhat wider than required.

The purpose of the invention is to increase the efficiency of exposure by correcting the image in the corners of the screen.

This goal is achieved by the method of forming a linear raster of color kinescopes with a slit mask, consisting in applying a photosensitive material to the screen panel of the kinescope, placing a slit shadow mask inside the panel, exposing the photosensitive material with light from a linear light source through the shadow mask slots, while At least one cylindrical lens is installed between the linear light source and the screen panel, and the longitudinal axis of the cylindrical lens is perpendicular to the longitudinal axis of the linear light source, simultaneously moving the screen panel and the cylindrical

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lens parallel to the longitudinal axis of the linear light source.

FIG. 1 shows an exposure device used to form a raster of color kinescopes, general view, axial section; in fig. 2 - tilt correction lens and linear light source, isometry; in fig. 3 - the same, with a plate installed between them with a hole, side view, section; in fig. 4 shows a screen panel on which sample images of a light source are projected onto it when a cylindrical lens is not installed, a general view; in fig. 5 is the same with the movement of the images of the light source projected onto it when the panel moves without a cylindrical lens, general view; in fig. 6, too, with the image of individual images of a light source being projected onto it when a cylindrical lens moves, a general view.

The exposure device (Fig. 1) is known as ma to 1, which is used in the formation of color kinescope rasters. The ma to 1 includes a light source box 2 and a support panel 3 bolted (not shown) to the bottom panel 4, which is fixed at a desired angle with legs 5. Linear light source b (typical mercury lamp) installed in the box 2 light source. Plate 7 with a hole located in the box above the linear light source. Hole 3 in plate 7 defines the effective length of the linear source 6 of light that is used during the exposure,

Directly above the opening 8 there is a tilt correction lens 9. Inside the supporting panel 3 there is a main corrective lens unit 10. The lens unit includes a diffuse correction lens 11 that refracts the light from the source in such a way that it has a trajectory similar to that of the electron beams during tube operation, and a lens of light intensity correction, which compensates for changes in light intensity in different parts of the beacon. The screen panel unit 12 is mounted on the support panel 3. The unit 12 includes a base panel panel 13 and a slit shadow mask 14 mounted inside the panel 13 by known methods. A photosensitive material 15 is deposited on the inner surface of the screen panel 13. During the formation of the raster, the photosensitive material 15 is exposed to light from a linear source 6 passing through a plate 7 with a hole, correcting

lens 9, filter 16, diffusing lens 11 and shadow mask 14.

FIG. 2 and 3 is a detailed depiction of the linear source 6 of the light and

lenses 9 tilt correction. Lens 9, usually cylindrical, is a solid piece of optical quartz and looks like a cylinder, cut parallel to the central axis and having, as

0 usually a convex cylindrical and flat surface. Linear light source 6 has the shape of a tube and may be of a mercury-arc type, such as a BH6 lamp, manufactured by General Electric. Pac5, positioned inside the tilt correction mapping 9, is oriented with its longitudinal axis A-A perpendicular to the longitudinal axis B-B of the linear source 6 of the light. As shown in FIG. 3. plate 7 with

A hole is installed between the light source 6 and the correction lens 9. Although it is possible to place the lens 9 directly on the opening 8, it is preferable to install it at a slight distance above the opening 8.

5 In accordance with the improvement of the described method of forming a raster, both the screen panel 13 and the cylindrical tilt correction lens 9 are synchronously moving in the Y-Y direction parallel to the longitudinal axis B-B of the linear light source 6. The movement of one screen panel leads to the fact that the image of the linear source 6 of light on it slightly moves from side to side to side.

5 corners of the panel. This small movement is significantly eliminated by the movement of the cylindrical lens 9 in synchronization with the movement of the panel 13.

The slope correction provided by the obstruction is visible from the comparison of FIG. 4.5 and 6. FIG. 4 shows the images 17 taken on the screen panel 13 from the linear light source 6 when the tilt correction lens 9 is not used. From the front, distant from the major axis X-X and the small axis Y-Y, are inclined at different angles depending on the distance to both axes. For the purpose of illustration, the dimensions of the images and the angles of inclination in FIG. 4 hard

0 exaggerated. FIG. 5 shows the movement of images of the light source 6 projected onto the screen panel 13 as a result of the movement of the panel. The tilt-correction lens 9 straightens the image 171 of the light source 6 so that they are oriented vertically and parallel to the minor axis Y-Y of the panel. However, the movement of the panel along the small Y-Y axis leads to a slight movement of the images 171 of the source 6 of the barking from side to side. In FIG. 6 shows the resultant pattern formed by images 17, which have a corrected tilt and are projected through a moving tilt correction lens 9 onto a moving panel. Formed straight lines.

The upper surfaces of the lenses described are generally defined as cylindrical. This definition recognizes that such a surface may be either strictly cylindrical or with some deviations from cylindricality. Depending on the specific applications of the invention, such deviations may be necessary to fully compensate for the inclination of the light source image in tubes having variable shadow mask contours, variable screen panel contours and variable distances from mask to screen.

It is preferable that tilt correction lenses are made of ultraviolet quartz, selected for its lightfastness. The passage of light into the lens should reach 90% after a 100-hour exposure to a 1 kW mercury arc lamp installed at a distance of 10 mm from the lens. In addition, the slopes of the X- and Y-components of the cylindrical surface of each lens should not deviate by more than ± 0.5 mrad from the specified values. The flat surface of each lens should have a planar characteristic within five interference rings of the same shape when using a helium laser. Both surfaces of each lens must be optically polished and have no visible haze.

The table shows the dimensions for certain cylindrical convex lenses, structurally similar to lens 9 in FIG. 2 and 3, quality zone - effective

the area of the lens that is used during the formation of the raster.

The amount of deviation of the screen panel 13 and lens 9 during exposure depends on the vertical dimensions of the jumpers. In some cases, the magnitude of the lens shift will be different from the magnitude of the panel shift. However, for one tube measuring 66 cm diagonally, it was determined that the amount of shear of +5.53 mm

close to optimum for both the panel and the lens.

Claims (1)

The invention The method of forming a linear raster of color picture tubes with a slit mask. including a photosensitive material applied to the screen panel of the screen, placing a slit shadow mask inside the screen panel and exposing the photosensitive material with light from a linear light source through the slits of the shadow mask, with at least one cylindrical lens installed between the linear light source and the screen panel and longitudinally cylindrical lens axis perpendicular to the longitudinal axis of the linear light source, characterized in that, in order to increase the exposure efficiency by correcting the image at the corners of the screen, the screen panel and the cylindrical lens are synchronously moved parallel to the longitudinal axis of the linear light source. Convex lens dimensions Total length Width Curvature radius Maximum thickness Quality zone length Quality zone width Growing from the center line of the source Sveta: To the flat surface of the lens To the plate with a hole Quantitative indication of dimensions, inch (mm) 2,500 (63,5) 2,000 (50.8) 3,900 (99.1) 0,300 (7,6) 1,800 (45.7) 1,800 (45.7) 0.500 (12.7) 0.280 (7.1) / Ni -a. with so -four Јb